The difference between mass and weight are defined and described in this student-lead NASA eClips segment. The resource also includes a lesson that contains a pre- and post-test, and an activity using the Frayer model. The Real World series of NASA...(View More) eClips™ connects classroom mathematics to 21st century careers and innovations and are designed for students to develop an appreciation for mathematics through real-world problem solving.(View Less)

Through the use of rhythm patterns of sounds presented in a solar system model, learners will collect data to determine orbital periods. Then, using that data, they will derive Kepler’s Third Law (the relationship between the distance of planets...(View More) from the sun and their orbital periods) and apply the equation to search for exoplanets in orbit around extrasolar systems. Educator resources include a 5E instructional lesson and alignments with Next Generation Science Standards (NGSS): ESS1.B: Earth and the Solar System. This resource is part of the Infiniscope space exploration experiences.(View Less)

Learners design and build an airbag system that can safely land an egg dropped from a height of 3' onto the floor. This resource includes a challenge video, leader notes, and handouts. Two supplemental videos are included: 1) An airbag landing...(View More) system in action as a NASA rover lands on Mars, and 2) NASA materials engineer Erick Ordoñez explaining how he makes sure that the materials NASA sends into space are problem-free. This challenge is part of Mission: Solar System, NASA and Design Squad® Nation, a series of hands-on activities and videos let kids apply science, technology, engineering, and math (STEM) skills to solve design challenges. Introductory resources include resources for running a challenge, introducing the design process, and tips for facilitating open-ended challenges.(View Less)

Using an online interactive platform, learners will explore our solar system from the perspective of the Sun. They will observe the motion of different worlds to determine their location in the solar system. Then they will launch probes to search...(View More) these small worlds (bodies in the solar system not classified as a planet or a moon) for the caches hidden on them in order to collect the astrocoins inside. A 5E instructional lesson allows students to analyze a model to locate small worlds, define speed/distance relationships, and identify model limitations. Images, worksheets and a rubric are included. Instructional objectives and learning outcomes are aligned with Next Generation Science Standards (NGSS); the NRC Framework for K-12 Science Education; Common Core State Standards for English Language Arts; and A Framework for 21st Century Learning. This resource is part of the Infiniscope space exploration experiences.(View Less)

This is the third module in the Solar Dynamic Observatory (SDO) Project Suite curriculum. Each activity is self-directed by students or student teams and utilizes online videos, data from the SDO satellite and hands-on activities to explore,...(View More) research and build knowledge about how the Sun's varying activity impacts Earth and space weather. Each activity provides opportunities to build knowledge and vocabulary, apply or demonstrate learning through real world connections and create resources to use in investigations. Both a teacher and student guide are included with sequential instructions and embedded links to the needed videos, tutorials and internet resources. In Activity 3A: Sun-Earth Interactions, students gather information from online videos and create a 3D model to demonstrate the relationship to Earth's place in space and the affect of Earth's axial tilt on our seasons, then film a short video explaining the reasons for the seasons. Activity 3B: Space Weather, students use online videos to gather information on what space weather is, and its causes and effects, to create a concept map. They then use real-time SDO data to forecast space weather. Activity 3C: Solar Research in Action! Make a Magnetometer has students view information in online videos about to Earth's magnetosphere and the impacts of space weather, then create a magnetometer to detect and visualize changes in the Earth's magnetic fields to monitor solar storm impacts. A computer for student-teams and access to the internet are needed for this module. See related and supplementary resources for link to full curriculum. The appendix includes an alignment to the Next Generation Science Standards (NGSS).(View Less)

This is the fourth and culminating module in the Solar Dynamic Observatory (SDO) Project Suite curriculum. Student teams use information and resources from the other three modules in the project suite to create a 3D interactive solar exhibit to...(View More) educate others about the Sun and how SDO informs scientists about the Sun's activity, structures and features, and Earth-Sun interactions. Students then self-evaluate their team's solar exhibit. Both a teacher and student guide are included, as well as tools for students to self-direct and track project process, and record reflections and information. A computer for student-teams and access to the internet are needed for this module. See related and supplementary resources for link to full curriculum. The appendix includes an alignment to the Next Generation Science Standards (NGSS).(View Less)

This is a lesson about the solar wind, Earth's magnetosphere, and the Moon. Participants will work in groups of two or three to build a model of the Sun-Earth-Moon system. They will use the model to demonstrate that the Earth is protected from...(View More) particles streaming out of the Sun, called the solar wind, by a magnetic shield called the magnetosphere, and that the Moon is periodically protected from these particles as it moves in its orbit around the Earth. Participants will also learn that the NASA ARTEMIS mission is a pair of satellites orbiting the Moon that measure the intensity of solar particles streaming from the Sun.(View Less)

This is an activity about using models to solve a problem. Learners will use a previously constructed model of the MMS satellite to determine if the centrifugal force of the rotating MMS model is sufficient to push the satellite's antennae outward,...(View More) simulating the deployment of the satellites after launch. Then, learners will determine the minimum rotational speed needed for the satellite to successfully deploy the antennae. This is the seventh activity as part of the iMAGiNETICspace: Where Imagination, Magnetism, and Space Collide educator's guide. Instructions for downloading the iBook educator's guide and the associated Transmedia book student guide are available at the resource link.(View Less)

Learners will weigh themselves on scales modified to represent their weights on other worlds to explore the concept of gravity and its relationship to weight. They consider how their weights would be the highest of all the planets while standing on...(View More) Jupiter, but their mass remains the same no matter where in the solar system they are. They compare the features of different planets to determine which characteristics cause a planet to have more or less gravity. This activity is part of Explore! Jupiter's Family Secrets, a series designed to engage children in space and planetary science in libraries and informal learning environments.(View Less)

Learners will model the gravitational fields of planets on a flexible surface. Children place and move balls of different sizes and densities on a plastic sheet to develop a mental picture of how the mass of an object influences how much effect it...(View More) has on the surrounding space. This activity is part of Explore! Jupiter's Family Secrets, a series designed to engage children in space and planetary science in libraries and informal learning environments.(View Less)